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// file      : build2/scope -*- C++ -*-
// copyright : Copyright (c) 2014-2016 Code Synthesis Ltd
// license   : MIT; see accompanying LICENSE file

#ifndef BUILD2_SCOPE
#define BUILD2_SCOPE

#include <unordered_set>
#include <unordered_map>

#include <butl/path-map>

#include <build2/types>
#include <build2/utility>

#include <build2/module>
#include <build2/variable>
#include <build2/prerequisite>
#include <build2/target-type>
#include <build2/rule-map>
#include <build2/operation>

namespace build2
{
  class scope
  {
  public:
    // Absolute and normalized.
    //
    const dir_path& out_path () const {return *out_path_;}
    const dir_path& src_path () const {return *src_path_;}

    // The first is a pointer to the key in scope_map. The second is a pointer
    // to the src_root/base variable value, if any (i.e., it can be NULL).
    //
    const dir_path* out_path_ = nullptr;
    const dir_path* src_path_ = nullptr;

    bool
    root () const {return root_ == this;}

    scope*
    parent_scope () const {return parent_;}

    // Root scope of this scope or NULL if this scope is not (yet)
    // in any (known) project. Note that if the scope itself is
    // root, then this function return this. To get to the outer
    // root, query the root scope of the parent.
    //
    scope*
    root_scope () const {return root_;}

    // Root scope of a strong amalgamation of this scope or NULL if
    // this scope is not (yet) in any (known) project. If there is
    // no strong amalgamation, then this function returns the root
    // scope of the project (in other words, in this case a project
    // is treated as its own strong amalgamation).
    //
    scope*
    strong_scope () const
    {
      return root_ != nullptr
        ? root_->strong_ != nullptr ? root_->strong_ : root_
        : nullptr;
    }

    // Root scope of the outermost amalgamation or NULL if this scope is not
    // (yet) in any (known) project. If there is no amalgamation, then this
    // function returns the root scope of the project (in other words, in this
    // case a project is treated as its own amalgamation).
    //
    scope*
    weak_scope () const
    {
      scope* r (root_);
      if (r != nullptr)
        for (; r->parent_->root_ != nullptr; r = r->parent_->root_) ;
      return r;
    }

    // Variables.
    //
  public:
    variable_map vars;

    // Lookup, including in outer scopes. If you only want to lookup in this
    // scope, do it on the the variables map directly (and note that there
    // will be no overrides).
    //
    lookup
    operator[] (const variable& var) const
    {
      return find (var).first;
    }

    lookup
    operator[] (const string& name) const
    {
      return operator[] (var_pool[name]);
    }

    // As above, but include target type/pattern-specific variables.
    //
    lookup
    find (const variable& var, const target_key& tk) const
    {
      return find (var, tk.type, tk.name).first;
    }

    lookup
    find (const string& var, const target_key& tk) const
    {
      return find (var_pool[var], tk);
    }

    lookup
    find (const variable& var, const target_type& tt, const string& tn) const
    {
      return find (var, &tt, &tn).first;
    }

    lookup
    find (const string& var, const target_type& tt, const string& tn) const
    {
      return find (var_pool[var], tt, tn);
    }

    pair<lookup, size_t>
    find (const variable& var,
          const target_type* tt = nullptr,
          const string* tn = nullptr) const
    {
      auto p (find_original (var, tt, tn));
      return var.override == nullptr ? p : find_override (var, move (p));
    }

    // Implementation details (used by scope target lookup). The start_depth
    // can be used to skip a number of initial lookups.
    //
    pair<lookup, size_t>
    find_original (
      const variable&,
      const target_type* tt = nullptr, const string* tn = nullptr,
      const target_type* gt = nullptr, const string* gn = nullptr,
      size_t start_depth = 1) const;

    pair<lookup, size_t>
    find_override (const variable&,
                   pair<lookup, size_t> original,
                   bool target = false) const;

    // Return a value suitable for assignment (or append if you only
    // want to append to the value from this scope). If the variable
    // does not exist in this scope's map, then a new one with the
    // NULL value is added and returned. Otherwise the existing value
    // is returned.
    //
    value&
    assign (const variable& var) {return vars.assign (var);}

    value&
    assign (const string& name) {return vars.assign (name);}

    // Unlike the two above, assign a typed non-overridable variable with
    // normal visibility.
    //
    template <typename T>
    value&
    assign (string name) {return vars.assign<T> (move (name));}

    // Return a value suitable for appending. If the variable does not
    // exist in this scope's map, then outer scopes are searched for
    // the same variable. If found then a new variable with the found
    // value is added to this scope and returned. Otherwise this
    // function proceeds as assign().
    //
    value&
    append (const variable&);

    value&
    append (const string& name) {return append (var_pool[name]);}

    // Target type/pattern-specific variables.
    //
    variable_type_map target_vars;

    // Prerequisite cache.
    //
  public:
    prerequisite_set prerequisites;

    // Meta/operations supported by this project (set on the root
    // scope only).
    //
    build2::meta_operations meta_operations;
    build2::operations operations;

    typedef build2::path path_type;

    // Set of buildfiles already loaded for this scope. The included
    // buildfiles are checked against the project's root scope while
    // imported -- against the global scope (global_scope).
    //
    std::unordered_set<path_type> buildfiles;

    // Target types.
    //
  public:
    target_type_map target_types;

    const target_type*
    find_target_type (const string&, const scope** = nullptr) const;

    // Given a name, figure out its type, taking into account extensions,
    // special names (e.g., '.' and '..'), or anything else that might be
    // relevant. Also process the name (in place) by extracting the
    // extension, adjusting dir/value, etc., (note that the dir is not
    // necessarily normalized). Return NULL if not found.
    //
    const target_type*
    find_target_type (name&, const string*& ext) const;

    // Dynamically derive a new target type from an existing one. Return the
    // reference to the target type and an indicator of whether it was
    // actually created.
    //
    pair<reference_wrapper<const target_type>, bool>
    derive_target_type (const string& name, const target_type& base);

    template <typename T>
    pair<reference_wrapper<const target_type>, bool>
    derive_target_type (const string& name)
    {
      return derive_target_type (name, T::static_type);
    }

    // Rules.
    //
  public:
    rule_map rules;

    // Modules.
    //
  public:
    loaded_module_map modules; // Only on root scope.

  private:
    friend class scope_map;
    friend class temp_scope;

    // These two from <build2/file> set strong_.
    //
    friend void create_bootstrap_outer (scope&);
    friend scope& create_bootstrap_inner (scope&, const dir_path&);

    scope () = default;

    scope* parent_;
    scope* root_;
    scope* strong_ = nullptr; // Only set on root sopes.
                              // NULL means no strong amalgamtion.
  };

  // Temporary scope. The idea is to be able to create a temporary
  // scope in order not to change the variables in the current scope.
  // Such a scope is not entered in to the scope map. As a result it
  // can only be used as a temporary set of variables. In particular,
  // defining targets/prerequisites directly in such a scope will surely
  // end up badly. Defining any nested scopes will be as if defining
  // such a scope in the parent (since path() returns parent's path).
  //
  class temp_scope: public scope
  {
  public:
    temp_scope (scope& p)
    {
      out_path_ = p.out_path_;
      src_path_ = p.src_path_;
      parent_ = &p;
      root_ = p.root_;
      // No need to copy strong_ since we are never root scope.
    }
  };

  // Note that the scope map is only for paths from the out tree.
  //
  using scope_map_base = butl::dir_path_map<scope>;

  class scope_map: public scope_map_base
  {
  public:
    // Note that we assume the first insertion into the map is always the
    // global scope.
    //
    iterator
    insert (const dir_path&, bool root);

    // Find the most qualified scope that encompasses this path.
    //
    scope&
    find (const dir_path&);

    scope&
    find (const path& p)
    {
      // Natural thing to do here would be to call find (p.directory ()).
      // However, there could be a situation where the passed path is a
      // directory (i.e., the calling code does not know what it is dealing
      // with), so let's use the whole path.
      //
      return find (path_cast<dir_path> (p));
    }
  };

  extern scope_map scopes;
  extern scope* global_scope;
}

#endif // BUILD2_SCOPE